Your search keyword '"Niels van Linden"' showing total 7 results

1. Physicochemical model for simulating the chemical processes during the crystallization of minerals from spent ion exchange regenerant

Author

Marc Arpad Boncz, Niels van Linden, Amir Haidari, Yundan Wang, and Henri Spanjers

Subjects

Brines, Sequential crystallisation, PHREEQC, Closed cycle, Metal recovery, Management. Industrial management, HD28-70

Abstract

Traditionally, industrial processes produce wastes that, even though often containing useful materials, are discarded, contributing to environmental pollution and depletion of natural resources. An example of such wastes are brines, flows of concentrated salts, produced in water treatment processes, which are now routinely discharged into receiving water bodies. Brines however can also be considered as flows of reusable materials which should be recovered, and the Zero Brine cooperation project aims to develop processes for that purpose. For a demineralized water production plant in the port of Rotterdam (the Netherlands), a closed water processing cycle was proposed to treat the large volume of spent Ion Exchange (IEX) regenerant brine which, apart from recovering demineralized water, is also intended to produce magnesium (Mg2+) and calcium (Ca2+) salts, with the highest purity possible, from the otherwise discharged brine. The process scheme includes nanofiltration (NF) for separating mono- and multivalent ions, followed by sequential chemical precipitation of Mg2+ and Ca2+ ions from the NF concentrate, and production of demineralized water by evaporation of the NF permeate. The concentrate of monovalent ions produced in the evaporator, essentially a concentrated sodium chloride solution, in its turn might be reused for IEX regeneration. Part of the supernatant of the sequential precipitation may be fed to the evaporator as well, but bleeding the other part of this supernatant is essential in order to maintain process stability, avoid accumulation of minor pollutants, and reduce scaling. In this study, various scenarios to operate the process were modeled, using PHREEQC and Excel. According to the simulation results, recovery of ≈97% of Mg2+ and Ca2+ is possible, the latter with a higher purity than the former. The main factors affecting the results are the concentration of carbonate present in the spent IEX regenerant, as well as characteristics of the NF membrane and the dosing of sodium hydroxide in the sequential precipitation steps. The results of the simulations were used for the design and operation of a pilot plant, comprising all mentioned process steps.

Published

2022

2. Separation of natural organic matter and sodium chloride for salt recovery purposes in zero liquid discharge

Author

Niels van Linden, Ran Shang, Georg Stockinger, Bas Heijman, and Henri Spanjers

Subjects

Brine, Separation, Nanofiltration, Electrodialysis, Ion exchange, SALEX, Management. Industrial management, HD28-70

Abstract

The application of zero liquid discharge (ZLD) results in the generation of solid residual streams, which are often not fit for reuse. In this study, we assessed the separation of natural organic matter (NOM) and sodium chloride (NaCl) by nanofiltration (NF), electrodialysis (ED) and ion exchange (IEX) in reverse osmosis brine (RO-brine) and by the extraction of impurities from salt (SALEX) in the generated mixed solids of a full-scale ZLD water treatment plant.The NaCl recovery by NF, ED and IEX ranged 69-99% and the rejection of NOM ranged 18–19%, 43–65% and 53–76%, respectively. The recovery of NaCl by SALEX ranged 52–99%, while the rejection of NOM ranged 59–92%. The results show that NOM and NaCl can be separated both in RO-brine and mixed solids, opening opportunities for recovery of reusable salt from brines in ZLD.

Published

2020

3. A solid oxide fuel cell fuelled by methane recovered from groundwater

Author

S. Ali Saadabadi, Niels van Linden, P.V. Aravind, and Abel Heinsbroek

Subjects

020209 energy, Strategy and Management, 02 engineering and technology, Combustion, Industrial and Manufacturing Engineering, Methane, Energy generation, chemistry.chemical_compound, Solid oxide fuel cell, 0202 electrical engineering, electronic engineering, information engineering, medicine, Drinking water, Groundwater, 0505 law, General Environmental Science, Waste management, Methane reformer, Renewable Energy, Sustainability and the Environment, 05 social sciences, Resource recovery, chemistry, Greenhouse gas, Carbon dioxide, 050501 criminology, Gas engine, Environmental science, Activated carbon, medicine.drug

Abstract

This study investigates the feasibility of electricity production in a solid oxide fuel cell using methane recovered from groundwater as the fuel. Methane must be removed from groundwater for the production of drinking water to, amongst others, avoid bacterial regrowth. Instead of releasing methane to the atmosphere or converting it to carbon dioxide by flaring, methane can also be recovered by vacuum stripping and served as a fuel. However, the electrical efficiency of currently used combustion-based technologies fuelled with methane-rich gas is limited to 35% due to the low heating value of the recovered gas (70 mol. % methane) and power derating due to the presence of carbon dioxide (25 mol.%). We propose to use a solid oxide fuel cell to use the methane-rich gas as fuel. Solid Oxide Fuel Cells are fuel-flexible and potentially attain higher electrical efficiencies up to 60%. To this end, specific gas processing, including cleaning and methane reforming, is required to allow for durable operation in a solid oxide fuel cell. We assessed whether electricity could be generated by a solid oxide fuel cell using methane recovered from a full-scale drinking water treatment plant as a fuel. The groundwater had a methane concentration of 45 mg∙L-1, and the recovered gas by vacuum towers contained 70 mol% methane. We used a gas cleaning reactor with impregnated activated carbon to remove hydrogen sulfide traces from the methane-rich gas. Thermodynamic calculations showed that additional steam is required to achieve a high methane reforming. The added steam and the carbon dioxide content in the recovered gas simultaneously contribute to the methane reforming to prevent carbon deposition. The measured open circuit potential corresponded with the theoretical Nernst voltage, implying high methane reforming in the solid oxide fuel cell. The achieved power density of the cell fuelled with the methane-rich gas (mixed with steam) was 27% less than the hydrogen-fuelled cell. Ultimately, 51.2% of the power demand of the plant can be covered by replacing the gas engine in a drinking water treatment with a 915 kW solid oxide fuel cell system fuelled by the methane recovered from the groundwater, while the greenhouse gas emission can be reduced by 17.6%.

Published

2021

4. Separation of natural organic matter and sodium chloride for salt recovery purposes in zero liquid discharge

Author

Bas Heijman, Georg Stockinger, Henri Spanjers, Niels van Linden, and Ran Shang

Subjects

lcsh:Management. Industrial management, Brine, Sodium, 0208 environmental biotechnology, Geography, Planning and Development, chemistry.chemical_element, 02 engineering and technology, 010501 environmental sciences, 01 natural sciences, Zero liquid discharge, Separation, SALEX, Reverse osmosis, 0105 earth and related environmental sciences, Water Science and Technology, Chromatography, Ion exchange, Electrodialysis, Nanofiltration, 020801 environmental engineering, chemistry, lcsh:HD28-70, Water treatment

Abstract

The application of zero liquid discharge (ZLD) results in the generation of solid residual streams, which are often not fit for reuse. In this study, we assessed the separation of natural organic matter (NOM) and sodium chloride (NaCl) by nanofiltration (NF), electrodialysis (ED) and ion exchange (IEX) in reverse osmosis brine (RO-brine) and by the extraction of impurities from salt (SALEX) in the generated mixed solids of a full-scale ZLD water treatment plant. The NaCl recovery by NF, ED and IEX ranged 69-99% and the rejection of NOM ranged 18–19%, 43–65% and 53–76%, respectively. The recovery of NaCl by SALEX ranged 52–99%, while the rejection of NOM ranged 59–92%. The results show that NOM and NaCl can be sepa-rated both in RO-brine and mixed solids, opening opportunities for recovery of reusable salt from brines in ZLD.

Published

2020

5. Recovery and applications of ammoniacal nitrogen from nitrogen-loaded residual streams: A review

Author

Zhe Deng, Niels van Linden, Jules B. van Lier, Henri Spanjers, and Elena Guillen

Subjects

Environmental Engineering, Nitrogen, 0208 environmental biotechnology, chemistry.chemical_element, 02 engineering and technology, 010501 environmental sciences, Management, Monitoring, Policy and Law, Waste Disposal, Fluid, 01 natural sciences, Rivers, Anaerobiosis, Ammoniacal nitrogen, Waste Management and Disposal, Kjeldahl method, 0105 earth and related environmental sciences, Total suspended solids, Resource recovery, Biological Oxygen Demand Analysis, Pollutant, Chemical oxygen demand, General Medicine, Pulp and paper industry, 020801 environmental engineering, Anaerobic digestion, chemistry, Environmental science

Abstract

Total ammoniacal nitrogen (TAN) is considered to be a pollutant, but is also a versatile resource. This review presents an overview of the TAN recovery potentials from nitrogen (N)-loaded residual streams by discussing the sources, recovery technologies and potential applications. The first section of the review addresses the fate of TAN after its production. The second section describes the identification and categorisation of N-loaded (≥0.5 g L−1 of reduced N) residual streams based on total suspended solids (TSS), chemical oxygen demand (COD), total Kjeldahl nitrogen (TKN), TAN, and TAN/TKN ratio. Category 1 represents streams with a low TAN/TKN ratio ( 1 g L−1) that require a decrease of the TSS prior to TAN recovery, whereas category 3 represents streams with a high TAN/TKN ratio (≥0.5) and low TSS (≤1 g L−1) that are suitable for direct TAN recovery. The third section focuses on the key processes and limitations of AD, which is identified as a suitable technology to increase the TAN/TKN ratio by converting organic-N to TAN. In the fourth section, TAN recovery technologies are evaluated in terms of the feed composition tolerance, the required inputs (energy, chemicals, etc.) and obtained outputs of TAN (chemical form, concentration, etc.). Finally, in the fifth section, the use of recovered TAN for three major potential applications (fertilizer, fuel, and resource for chemical and biochemical processes) is discussed. This review presents an overview of possible TAN recovery strategies based on the available technologies, but the choice of the recovery strategy shall ultimately depend on the product characteristics required by the application. The major challenges identified in this review are the lack of information on enhancing the conversion of organic-N into TAN by AD, the difficulties in comparing the performance and required input of the recovery technologies, and the deficiency of information on the required concentration and quality of the final TAN products for reuse.

Published

2021

6. Application of dynamic current density for increased concentration factors and reduced energy consumption for concentrating ammonium by electrodialysis

Author

Jules B. van Lier, Niels van Linden, and Henri Spanjers

Subjects

Osmosis, Environmental Engineering, 0208 environmental biotechnology, Electro-osmosis, 02 engineering and technology, 010501 environmental sciences, 01 natural sciences, chemistry.chemical_compound, Ammonium Compounds, Back-diffusion, Concentration factor, Ammonium, Fertilizers, Waste Management and Disposal, 0105 earth and related environmental sciences, Water Science and Technology, Civil and Structural Engineering, Sewage, Ecological Modeling, Water, Electrodialysis, Energy consumption, Pulp and paper industry, Pollution, 020801 environmental engineering, chemistry, Current efficiency, Concentration gradient, Current density

Abstract

Ammonium (NH4+) can be recovered from water for fertiliser production or even energy production purposes. Because NH4+ recovery is more effective at increased concentrations, electrodialysis (ED) can be used to concentrate NH4+ from side streams, such as sludge reject water, and simultaneously achieve high NH4+ removal efficiencies. However, the effect of osmosis and back-diffusion increases when the NH4+ concentration gradient between the diluate and the concentrate stream increases, resulting in a limitation of the concentration factor and an increase in energy consumption for NH4+ removal. In this study, we showed that operation at dynamic current density (DCD) reduced the effect of osmosis and back-diffusion, due to a 75% decrease of the operational run time, compared to operation at a fixed current density (FCD). The concentration factor increased from 4.5 for an FCD to 6.7 for DCD, while the energy consumption of 90% NH4+ removal from synthetic sludge reject water at DCD remained stable at 5.4 MJ·kg-N−1.

Published

2019

7. Bipolar membrane electrodialysis for energetically competitive ammonium removal and dissolved ammonia production

Author

Niels van Linden, David A. Vermaas, Jules B. van Lier, Giacomo L. Bandinu, and Henri Spanjers

Subjects

020209 energy, Strategy and Management, 02 engineering and technology, Ammonia recovery, Industrial and Manufacturing Engineering, Ammonia production, chemistry.chemical_compound, Ammonia, 0202 electrical engineering, electronic engineering, information engineering, Water treatment, Ammonium, Ammoniacal nitrogen, 0505 law, General Environmental Science, Renewable Energy, Sustainability and the Environment, Chemistry, 05 social sciences, Building and Construction, Electrodialysis, Pulp and paper industry, Energy consumption, 050501 criminology, Hydroxide, Current efficiency, Acid–base reaction, Water dissociation

Abstract

Removal of ammoniacal nitrogen from residual waters traditionally relies on energy-consuming biochemical processes, while more novel alternative strategies focus on the recovery of total ammoniacal nitrogen for the production of fertilisers or the generation of energy. The recovery of total ammoniacal nitrogen as gaseous ammonia is more effective at high ammonia concentrations in the liquid feed. Typically, chemicals are added to increase the solution pH, whilebipolar membrane electrodialysis can be used to convert salt solutions to acid and base solutions by using only electricity. In this study, we used bipolar membrane electrodialysis to remove ammonium from water and to simultaneously produce concentrated dissolved ammonia, without using chemicals. The energy consumption and current efficiency to transport ammonium from the diluate (the feed water) were assessed throughout sequencing batch experiments.The total ammoniacal nitrogen removal efficiency for bipolar membrane electrodialysis ranged between 85 and 91% and the energy consumption was stable at 19 MJ·kg-N−1, taking both electrochemical and pumping energy into account. The base pH increased from 7.8 to 9.8 and thetotal ammoniacal nitrogen concentration increased from 1.5 to 7.3 g L−1, corresponding to a final ammonia concentration of 4.5 g L−1 in the base. Leakage of hydroxide, diffusion of dissolved ammonia and ionic species from the base to the diluate all contributed to a loss in current efficiency. Due to the increase in operational run time and concentration gradients throughout the sequencing batch experiments, the current efficiency decreased from 69 to 54%. We showed thatbipolar membrane electrodialysis can effectively be used to simultaneously remove ammonium from water and produce concentrated dissolved ammonia while avoiding the use of chemicals. Moreover, the energy consumption was competitive with that of the combination of electrodialysis and the addition of chemicals (22 MJ·kg-N−1).

Published

2020